KR20120050010A - A reinforcement method of weak stratum use of suction drainage - Google Patents

Abstract

PURPOSE: A suction drainage reinforcement method of a weak soil foundation is provided to efficiently discharge water of decrepitation in a weak soil foundation in short time by using natural filtration materials and a suction device. CONSTITUTION: A suction drainage reinforcement method of a weak soil foundation is as follows. An outer casing is inserted into a weak soil foundation up to a required length. A porous inner suction pipe(20) is constructed in the inner center of the outer casing. A space formed between the outer casing and inner suction pipe is filled with a filter media(30). The outer casing is pulled out from the weak soil foundation after filling is completed. The upper part of the filter media is sealed by using a sealing material(40). The upper part of the suction pipe is connected to a suction pipeline(50) where a vacuum pump(60) is constructed. The water of decrepitation in the weak soil foundation is discharged by operating the vacuum pump. The suction pipe is eliminated and the inner suction pipe is pulled out after discharging of the water of decrepitation is completed. A space where the inner suction pipe located is filled.

Description

 A Reinforcement method of weak stratum use of suction drainage

The present invention is a soft ground reinforcement technology for reinforcing soft ground in the construction of sewage or water supply facilities.

A lot of techniques are used to reinforce the soft ground.

The soft ground reinforcement method can be roughly divided into a method of reinforcing the ground itself and a method of securing support by driving piles.

It can be distinguished from the case of constructing heavy man-made workpieces such as buildings on the ground and the ground reinforcement which does not have access to the work site, improves workability, or does not require relatively large support capacity.

Piling method is the most reliable reinforcement method for securing large bearing capacity, but it is expensive.

The method of reinforcing the ground itself is mainly used to increase the bearing capacity by discharging the pore water in the ground, and in the case of small scale, a method of replacing the soil with high quality soil is also used.

Small-scale sewage treatment plant facilities such as small-scale equipment installations and village sewage facilities do not require large support for water supply or sewage construction, but many construction sites are in soft ground areas and the construction periods are often short.

Therefore, the soft ground reinforcement method that requires a long time, such as the method using consolidation by the soil, is often difficult to apply, and the method of reinforcing with piles is often expensive.

Ordinary sand drain or paper drain methods also require feminine soil, which is also difficult to apply due to time constraints.

As a quick reinforcement method, a suction drainage method is used, but the conventional methods are expensive because they discharge the gap water in the soft ground by using a pack of special geotextiles or using a permeable hollow pile or a specially made absorbing plate. There was a problem that the procurement period of the construction material is long, and the fine clay particles prevent the pores from being discharged well because the pores of the permeable material are blocked.

In addition, the sand drain method is used, and a quicklime pile is separately installed at an intermediate position where the gap water is not easily discharged between the sand drain and the sand drain, and the pore water is removed by using the chemical and physical properties of the quicklime. In addition, the construction cost increases because the same number of quicklime piles must be installed separately.

In addition, since the suction drainage speed is relatively slow, it takes time, and during this period, there was a problem in that the power cost was expensive because the vacuum pump was continuously operated.

The present invention is to effectively discharge the gap water in the soft ground in a short time by using a natural filtration material and a suction device, and to provide an economic soft ground reinforcement method.

Penetrating the outer casing into the soft ground to the required length:

Laying a porous inner suction pipe at an inner center of the outer casing;

Filling a filter medium into a space formed between the outer casing and the inner suction pipe;

Removing the outer casing from the soft ground after the filling of the filter medium is completed;

Sealing the upper part of the filter medium with a sealing material:

Connecting an upper portion of the inner suction pipe to a suction pipe installed with a vacuum pump;

Operating a vacuum pump to discharge gap water in the soft ground;

Removing the suction pipe after the pore water discharge is completed and lifting the internal suction pipe; And

It provides a method for reinforcing soft ground for embedding the conduit, characterized in that the step of filling the space in which the internal suction pipe is lifted.

The present invention is easy to obtain, easy to fill, and can be discharged in a short period of time by a vacuum pump using an internal suction pipe composed of sand and porous tubes with good water permeability, it is safe against the variation of the ground In addition, it is economical and shortens the construction period by reinforcing the soft ground in a short time.

1 is an exemplary view showing a configuration of the present invention.
Figure 2 is an illustration of applying the quicklime pile of the present invention.
3 is a plan view showing the effect of the quicklime pile of the present invention.
4 is an exemplary view in which a shielding film is installed on the ground of the present invention.
5 is an exemplary view showing a configuration of an internal suction pipe of the present invention.
6 is an exemplary view showing a pressure change state in the suction pipe of the present invention.

As shown in FIG. 1, the outer casing 10 is installed on the soft ground at regular intervals.

The outer casing vertically penetrates the outer casing to a predetermined depth while digging the soft ground using an auger placing machine.

When the installation of the outer casing is completed, the porous inner suction pipe 20 is vertically laid vertically to the same depth perpendicular to the center of the outer casing, and the upper part is temporarily fixed so that the center does not move.

The internal suction pipe is installed to protrude to the ground, and from the part close to the ground, the protruding portion is free of holes in the wall of the pipe.

When the above operation is completed, the filter medium 30 is filled in the space formed between the outer casing 10 and the inner suction pipe 20.

It is preferable to use relatively coarse sand having an effective diameter of 2 to 5 mm, but the effective diameter of the filter medium may be changed according to the characteristics of the soft ground.

When the filling of the filter medium is completed, the outer casing is lifted and removed using a pouring machine, and the upper portion of the filter medium filled between the outer casing and the inner suction pipe is sealed with the sealant 40 as shown in FIG.

Preferably, the sealant is made of plain expanded concrete or soil cement, and in order to facilitate the drawing of the inner suction pipe 20 later, the contact portion with the inner suction pipe is preferably inserted with a release material or an elastic body.

When the operation is completed, the suction pipe 50 is laid on the soft ground, and the vacuum pump 60 is connected to the end of the suction pipe.

The suction pipe 50 and the upper portion of each of the internal suction pipe 20 is connected to maintain the airtight.

When the above operation is completed, the vacuum pump is operated, and when the vacuum pump is operated, the pressure in the internal suction pipe is reduced to a vacuum state, so that the void water in the soft ground is sucked into the internal suction pipe through the filter medium, and the void water is sucked into the suction pipe. It is discharged to the outside through the vacuum pump via (50).

While operating the vacuum pump as described above, if the appropriate ground strength is secured by measuring the degree of gap water discharged in the soft ground, the operation of the vacuum pump is stopped, the suction pipe 50 is removed, and the internal suction pipe 20 is closed. Lifting it with a pourer and removing it, filling the space where the internal suction pipe is removed with soil or sand, completes the soft ground reinforcement.

Depending on the characteristics of the soft ground, it may take a long time to obtain the required ground strength only by the soft ground reinforcement method as described above, or it may be difficult to lower the water content ratio of the ground further.

In such a case, the suction pipe 50 is alternately removed one by one during the operation, and the quicklime pile 70 is formed by filling the quicklime in the form of granules or powder in the inside of the removed internal suction pipe 20, and then placing the pouring machine. Lift and remove the inner suction pipe and then seal the top of the quicklime pile as shown in FIG.

When the operation is completed, the vacuum pump is operated to suck and discharge the remaining gap water in the soft ground through the remaining inner suction pipe.

As described above, the quicklime absorbs the gap water in the soft ground, generates heat by hydration, and pressurizes the surrounding soft ground while expanding the volume twice or more, so that the number of remaining gaps in the soft ground is increased. The synergistic effect of the pressure generated by the quicklime pile and the suction force of the remaining inner suction pipe is discharged by moving toward the remaining inner suction pipe rapidly.

As described above, the quicklime pile is hardened over time after expansion by hydration to form a solid pile, and the strength of the ground increases with the surrounding ground hardened by pressure.

In addition, since the ground of the large area around the inner suction pipe is further discharged due to the pressure action of the quicklime pile and the suction action of the inner suction pipe, the ground strength is further increased.

When all of the above work is completed, depending on the ground conditions, the soil inside the hole in which the remaining inner suction pipe (20) is removed is filled with earth and sand, or, if more strength is required, the quicklime is filled into the hole to form the quicklime pile. .

In FIG. 3, the small circle in the center represents the quicklime pile 70, the circle of A represents the range of the effect of inhalation (dehydration) of the pore water discharge by inhalation, and the circle of B is used by the quicklime pile, It indicates that the gap water is absorbed, the volume is expanded, and the pressure is applied to the surrounding soft ground to further expand the pore water discharge influence range, and that the gap water is continuously sucked in and discharged from the remaining inner suction pipe 20. will be.

Depending on the soil composition, there are also soft grounds with breathable strata on the ground.

In the above case, when the pressure of the internal suction pipe 20 becomes a vacuum, air is sucked in from the ground surface and thus becomes a limiting factor in that no vacuum is formed or a high vacuum cannot be formed. Sometimes the capacity of the vacuum pump becomes excessively necessary.

In this case, as shown in FIG. 4, the shielding membrane 80 is installed on the ground, and the portion where the shielding membrane 80 and the inner suction pipe 20 meet is sealed with a filler such as silicon to prevent air from passing through.

It is preferable to use an inexpensive vinyl membrane for the shielding membrane, but there is no particular limitation on the material, so any shielding membrane can be used.

In this way, the pressure of the internal suction pipe can be maintained at a high vacuum regardless of the ground conditions, so that the gap water discharge can be made much faster and more efficiently, and the construction period can be shortened.

When the inner suction pipe 20 is used as a simple porous tube, 100% of the water remaining inside the inner suction pipe cannot be removed. When the depth of the inner suction pipe is deep, the remaining water inside is absorbed back into the ground to lower the ground strength. In addition, rapid heating of the quicklime hydration occurs during the quicklime, the quicklime can not be filled and the safety of the worker may be threatened.

In order to prevent the above problems, the inner suction pipe 20 of the present invention is formed as a porous tube 20a, the inside is formed of a hollow tube 20b, and the upper part is sealed with a cap 20c as shown in FIG. do.

When configured as described above, the water sucked into the internal suction pipe 20 can be discharged without leaving the bottom portion to the bottom, thereby preventing the ground from being soft again, and also preventing the risk of rapid hydration during quicklime filling.

In the suction drainage method, the vacuum pump is continuously operated for drainage of the pore water, which results in a high power cost.

In the present invention, the electric vacuum gauge 100 is installed in the suction pipe 50 immediately before the vacuum pump 60, the check valve 90 is installed, and the vacuum signal is transmitted to the automatic control panel 110 to designate the pressure of the vacuum gauge. Only when the value is less than the value, the vacuum pump 60 is automatically operated to reduce the operation time by reducing the operating time.

The state of pressure change in the suction pipe when the reverse valve 90 is provided in the suction pipe and the vacuum pump is periodically operated is as shown in FIG.

10 outer casing
20 internal suction line
30 filter ash
40 sealant
50 suction line
60 vacuum pumps
70 Quicklime Stakes
80 Shielding Membrane
90 reverse
100 vacuum gauge
110 automatic control panel

Claims (6)

Penetrating the outer casing 10 penetrating into the soft ground to the required length:
Laying a porous inner suction pipe (20) in the inner center of the outer casing;
Filling a filter medium (30) in a space formed between the outer casing and the inner suction pipe;
Removing the outer casing from the soft ground after the filling of the filter medium is completed;
Sealing the upper portion of the filter medium with a sealant (40):
Connecting an upper portion of the inner suction pipe to a suction pipe 50 on which a vacuum pump 60 is installed;
Operating a vacuum pump to discharge gap water in the soft ground;
Removing the suction pipe after the pore water discharge is completed and lifting the internal suction pipe; And
Suction drainage reinforcement method of the soft ground, characterized in that the step consisting of filling the space in which the internal suction pipes. Penetrating the outer casing 10 penetrating into the soft ground to the required length:
Laying a porous inner suction pipe (20) in the inner center of the outer casing;
Filling a filter medium (30) in a space formed between the outer casing and the inner suction pipe;
Removing the outer casing from the soft ground after the filling of the filter medium is completed;
Sealing the top of the filter medium with a sealant (40):
Connecting an upper portion of the inner suction pipe to a suction pipe 50 on which a vacuum pump 60 is installed;
Operating a vacuum pump to discharge gap water in the soft ground;
Removing the suction pipe after the discharge of the pore water is completed, filling quicklime into the internal suction pipe, and then lifting the internal suction pipe; And
Sealing the upper part of the quicklime filled to form a quicklime pile (70), the method of reinforcing the intake drainage of the soft ground, characterized in that the gap water is further discharged by the physical hydration action of the quicklime's chemical hydration and expansion. The method of claim 1 or 2, wherein the ground is blocked with a shielding membrane (80) to maintain a high vacuum. The method of claim 2, wherein the inner suction pipe is filled with quicklime by means of a zig-zag, and the remaining inner suction pipe discharges the gap water by vacuum. The method of claim 1 or 2, wherein the inner suction pipe (20) is composed of a porous tube (20a) and a hollow tube (20b), the suction ground reinforcement method of the soft ground. According to claim 1, the suction valve 50 is provided with a reverse valve 100 and receives the pressure signal of the vacuum gauge 100, the automatic control panel 110 automatically starts and stops the vacuum pump 60 in the set pressure range. Suction drainage reinforcement method of the soft ground, characterized in that the.

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